Serpantin ekolojisi ve Türkiye serpantin florası’na katkılar
Year 2017,
Volume: 5 Issue: 1, 22 - 33, 30.06.2017
Ebru Özdeniz
,
Beste Gizem Özbey
Latif Kurt
Ayşenur Bölükbaşı
Abstract
Türkiye’nin floristik çeşitliliğinin en önemli nedenlerinden bazıları, edafik, jeolojik ve jeomorfolojik çeşitlilik ve farklı topoğrafik yapılardır. Serpantin, jips gibi minerallerce zengin kayaçlar üzerinde gelişen topraklarda endemizmin yoğun olması “jeolojik izolasyon” ile açıklanmakta, bu bölgeler “jeolojik ada” ya da “edafik ada” olarak adlandırılmaktadır. Serpantinli kayaçlardan gelişen topraklar bitki gelişimi için ekstrem habitatlardır. Bu ekstrem habitat koşulları floristik çeşitlilik açısından, özellikle endemik ve nadir taksonlar açısından son derece zengindir. Serpantin habitatlarda uzmanlaşmış türler, bu yoğun stres faktörlerine karşı adaptasyonlar geliştirerek hayatta kalmaktadır. Serpantin sistemlerin ekolojisi, biyoçeşitliliğin sürdürülebilirliği ve türlerin korunabilmesi açısından büyük önem taşımaktadır.
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Serpentine ecology and contributions to the serpentine flora of Turkey
Year 2017,
Volume: 5 Issue: 1, 22 - 33, 30.06.2017
Ebru Özdeniz
,
Beste Gizem Özbey
Latif Kurt
Ayşenur Bölükbaşı
Abstract
Some of the most important reasons for the floristic diversity of Turkey are the edaphic, geological and geomorphogical diversity and different topographical structures. The fact that there is an extensive endemism on the land developed from the gypsum and serpentine rocks with extreme conditions is explained by the ‘’geological isolation’’ and these regions are called “geologic island“ or “edaphic island”. Serpentine soils are extreme habitats for plants. These extreme habitat conditions are rich with floristic diversity, especially endemic and rare taxa. The species which are specialist for serpentine habitats can survive by developing adaptations toward these intense stress conditions. The ecology of serpentine systems have a significant importance for the sustainability of biodiversity and preservation of species.
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Eker I, Koyuncu M, 2008. Muscari babachii sp. nov.(Hyacinthaceae) from south Anatolia. Nordic Journal of Botany 26(1‐2): 49-52.
Ekşi G, Koyuncu M, Bona M, 2015. Allium phanerantherum subsp. involucratum (Amaryllidaceae), a new subspecies from Turkey. Bangladesh Journal of Plant Taxonomy 22(2): 143-146
Freitag H, Özhatay E, 1997. A new subspecies of Salsola canescens (Chenopodiaceae) from SW Anatolia, Turkey. Willdenowia 185-190
Futuyma DJ, Moreno G, 1988. The evolution of ecological specialization. Annual Reviews Ecology and Systematics 19: 207–233
Gall JE, Rajakaruna N, 2013. The physiology, functional genomics, and applied ecology of heavy metal-tolerant Brassicaceae. In Brassicaceae: Characterization, functional genomics and health benefits. Edited by Minglin Lang, 121–148. Hauppauge, NY: Nova Science Gaston KJ, Blackburn TM, 2000. Pattern and Process in Macroecology. Blackwell Science, Oxford. Genç İ, Özhatay N, 2013. Allium serpentinicum and A. kandemirii (Alliaceae), two new species from East Anatolia, Turkey. In Annales Botanici Fennici, Finnish Zoological and Botanical Publishing Board 50: 50-54
Gordon A, Lipman CB, 1926. Why are serpentine and other magnesian soils infertile? Soil Science 22:291-302
Gustafson DJ, Casper BB, 2004. Nutrient addition affects AM fungal performance and expression of plant/fungal feedback in three serpentine grasses. Plant and Soil 259(1–2): 9–17
Gültepe M, Coşkunçelebi K, Makbul S, Sağlam C, 2015. Tragopogon turcicus sp. nov.(Asteraceae) from Turkey and its phylogenetic position. Nordic Journal of Botany 33(5): 540-547
Hamzaoğlu E, Koç M, Budak Ü, 2013. Galatella anatolica sp. nov.(Asteraceae: Astereae) from Osmaniye, Turkey. Nordic Journal of Botany 31(1): 087-089
Hamzaoğlu E, Koç M, Aksoy A, 2014. A new pricking Carnation (Caryophyllaceae) grows on tuff from Turkey: Dianthus aculeatus sp. nov. Biodicon 7(2): 159-162
Hamzaoğlu E, Koç M, Büyük İ, Aksoy A, Soydam Aydın A, 2015. A new serpentine-adapted carnation (Caryophyllaceae) from Turkey: Dianthus serpentinus sp. Nov. Nordic Journal of Botany 33:57-63
Hamzaoğlu E, Koç M, Aksoy A, 2015. Dianthus aticii, a new species from Turkey (Caryophyllaceae). PhytoKeys (48): 21
Harrison S, 1997. How natural habitat patch- iness affects the distribution of diversity in Californian serpentin chaparral. Ecology 78:1898-1906
Harrison S, 1999. Local and regional diversity in a patchy landscape: native, alien, and en- demic herbs on serpentine. Ecology 80: 70- 80
Hirth G, Guillot S, 2013. Rheology and tectonic significance of serpentinite. Elements 9(2): 107–113.
Hoşgören MY, 2000. Jeomorfolojinin Ana Çizgileri I, Rebel yayıncılık, İstanbul Iturralde RB, 2001. The influence of ultramafic soils on plants in Cuba. South African Journal of Science 97:510- 12
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Jenny H, 1980. The Soil Resource: Origin and Behavior. New York: Springer-Verlag. 377 pp
Kantarcı D, 1987. Toprak İlmi, İstanbul Üniversitesi Orman Fakültesi yayını, İstanbul
Kazakou E, Dimitrakopoulos PG, Baker AJM, Reeves RD ve Troumbis AY, 2008. Hypotheses, mechanisms and trade-offs of tolerance and adaptation to serpentine soils: From species to ecosystem level. Biological Reviews 83(4): 495–508
Koç M, Hamzaoğlu E, 2016. Eremogone ali-gulii (Caryophyllaceae), a new species from Turkey. PhytoKeys (61), 93
Krause W, 1958. Andere Bodenspezialisten. In Handbuch der Pflanzenphysiologie, ed. G Michael, 4:758-806. Berlin: Springer-Verlag
Kruckeberg AR, 1954. The ecology of serpentine soils: A symposium. III. Plant species in relation to serpentine soils. Ecology 35:267- 74
Kruckeberg AR, 1985. California Serpentines: Flora, Vegetation, Geology, Soils, and Management Problems. Berkeley: Univ. Calif. Press. 180 pp
Kruckeberg AR, 2002. The influences of lithology on plant life. In Geology and Plant Life: The Effects of Landforms and Rock Type on Plants, pp. 160-81. Seattle/London: Univ. Wash. Press. 362 pp.
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